SENSITIVITY AND SPECIFICITY OF RADIOGRAPHIC DETECTION OF CANINE ELBOW INCONGRUENCE IN AN IN VITRO MODEL

Canine elbow incongruence is believed to be the consequence of underdevelopment of the radius. The purpose of this study is to determine the sensitivity and specificity of radiography to detect elbow incongruence in an in vitro model and to assess the optimal elbow angle and radiographic beam position. Five normal cadaveric canine left forelimbs were used. A four‐pin, type 1 external fixator with a linear motor side bar was fixed to the cranial part of the radius of each limb and a 1 cm segment of bone was removed from the mid‐diaphysis to allow radial shortening. Each elbow was subjected to the same protocol. They were radiographed at two different angles (90° and 135°) of flexion, with 10 different radiographic beam positions (centered on the humeral condyle, 3 cm cranial, 3 cm caudal, 3 cm distal, 3 cm proximal, 3 cm cranio‐proximal, 3 cm cranio‐distal, 3 cm caudo‐proximal, 3 cm caudo‐distal and on the shoulder joint) and at four different level of radial shortening (0, 1, 2 and 3 mm). In addition, a radiographic view centered on the elbows flexed at 135° was made after simulating weight bearing. The acquired digital images were independently evaluated by three evaluators unaware of the elbows status. The elbows were judged normal, incongruent or borderline based on specific criteria. The sensitivity for detection of elbow incongruence at and beyond 2 mm was excellent at 90° (median=100% for all views) and good at 135° (median=80%) of flexion with no difference between examiners. The sensitivity at 1 mm of incongruence was unchanged at 135° but was reduced at 90° of flexion (median=60%) with a significant difference between the evaluators. The specificity was significantly different between the evaluators and ranged from 70% to 90% at 90° of flexion and from 50% to 80% at 135°. The lowest specificities at 90° were obtained with the proximal displacements of the X‐ray beam. Simulating weight bearing significantly decreased the sensitivity at 1 mm (from 80% to 50%) and 3 mm (from 100% to 80%) of incongruence and slightly increased the specificity (from 55% to 65%). Radiography is a sensitive and specific test to detect moderate‐to‐severe radio‐ulnar incongruence (2 mm and over) if the elbow is flexed at a 90° angle regardless of the radiographic beam position. Finally, canine elbow incongruence appeared reduced after an in vitro weight‐bearing simulation.